Timing operations in an IC with configurable circuits

ABSTRACT

Some embodiments provide a method that identifies a first physical design solution for positioning several configurable operations on several reconfigurable circuits of an integrated circuit (IC). The method identifies a second physical design solution for positioning the configurable operations on the configurable circuits. One of the identified physical design solutions has one reconfigurable circuit perform a particular configurable operation in at least two reconfiguration cycles while the other identified solution does not have one reconfigurable circuit perform the particular configurable operation in two reconfiguration cycles. The method costs the first and second physical design solutions. The method selects one of the two physical design solutions based on the costs.

FIELD OF THE INVENTION

The present invention is directed towards concurrent optimization of physical design and operational cycle assignment.

BACKGROUND OF THE INVENTION

The use of configurable integrated circuits (“IC's”) has dramatically increased in recent years. One example of a configurable IC is a field programmable gate array (“FPGA”). An FPGA is a field programmable IC that often has logic circuits, interconnect circuits, and input/output (I/O) circuits. The logic circuits (also called logic blocks) are typically arranged as an internal array of circuits. These logic circuits are connected together through numerous interconnect circuits (also called interconnects). The logic and interconnect circuits are often surrounded by the I/O circuits.

FIG. 1 illustrates an example of a configurable logic circuit 100. This logic circuit can be configured to perform a number of different functions. As shown in FIG. 1, the logic circuit 100 receives a set of input data 105 and a set of configuration data 110. The configuration data set is stored in a set of SRAM cells 115. From the set of functions that the logic circuit 100 can perform, the configuration data set specifies a particular function that this circuit has to perform on the input data set. Once the logic circuit performs its function on the input data set, it provides the output of this function on a set of output lines 120. The logic circuit 100 is said to be configurable, as the configuration data set “configures” the logic circuit to perform a particular function, and this configuration data set can be modified by writing new data in the SRAM cells. Multiplexers and look-up tables are two examples of configurable logic circuits.

FIG. 2 illustrates an example of a configurable interconnect circuit 200. This interconnect circuit 200 connects a set of input data 205 to a set of output data 210. This circuit receives configuration data bits 215 that are stored in a set of SRAM cells 220. The configuration bits specify how the interconnect circuit should connect the input data set to the output data set. The interconnect circuit 200 is said to be configurable, as the configuration data set “configures” the interconnect circuit to use a particular connection scheme that connects the input data set to the output data set in a desired manner. Moreover, this configuration data set can be modified by writing new data in the SRAM cells. Multiplexers are one example of interconnect circuits.

FIG. 3 illustrates a portion of a prior art configurable IC 300. As shown in this figure, the IC 300 includes an array of configurable logic circuits 305 and configurable interconnect circuits 310. The IC 300 has two types of interconnect circuits 310 a and 310 b. Interconnect circuits 310 a connect interconnect circuits 310 b and logic circuits 305, while interconnect circuits 310 b connect interconnect circuits 310 a to other interconnect circuits 310 a. In some cases, the IC 300 includes hundreds or thousands of logic circuits 305 and interconnect circuits 310.

Some have recently suggested configurable IC's that are reconfigurable at runtime. The development of reconfigurable IC technology is relatively in its early stages. One area of this technology that has not yet been fully developed is how to assign different operations that the reconfigurable IC performs to different configuration periods during runtime. Accordingly, there is a need for a method of designing reconfigurable IC's that uses novel techniques to assign different operations performed by the reconfigurable IC to different configuration periods during runtime.

SUMMARY OF THE INVENTION

Some embodiments provide a method that identifies a first physical design solution for positioning several configurable operations on several reconfigurable circuits of an integrated circuit (IC). The method identifies a second physical design solution for positioning the configurable operations on the configurable circuits. One of the identified physical design solutions has one reconfigurable circuit perform a particular configurable operation in at least two reconfiguration cycles while the other identified solution does not have one reconfigurable circuit perform the particular configurable operation in two reconfiguration cycles. The method costs the first and second physical design solutions. The method selects one of the two physical design solutions based on the costs.

BRIEF DESCRIPTION OF THE DRAWINGS

The novel features of the invention are set forth in the appended claims. However, for purpose of explanation, several embodiments of the invention are set forth in the following figures.

FIG. 1 illustrates an example of a configurable logic circuit.

FIG. 2 illustrates an example of a configurable interconnect circuit.

FIG. 3 illustrates a portion of a prior art configurable IC.

FIG. 4 illustrates an example of a configurable logic circuit that can perform a set of functions.

FIG. 5 illustrates an example of a configurable interconnect circuit.

FIG. 6 illustrates an example of a configurable node array that includes configurable nodes that are arranged in rows and columns.

FIG. 7 illustrates an example of a reconfigurable logic circuit.

FIG. 8 illustrates an example of a reconfigurable interconnect circuit.

FIG. 9 conceptually illustrates an example of a sub-cycle reconfigurable IC.

FIG. 10 illustrates a set of Boolean gates that compute two functions based on a set of inputs.

FIG. 11 illustrates the design of FIG. 10 after its gates have been placed into four groups.

FIG. 12 illustrates another representation of the design of FIG. 10.

FIG. 13 illustrates a circuit representation of one such storage/interconnect circuit.

FIG. 14 illustrates an example of an IC design that includes seventy-two design components.

FIG. 15 illustrates a path through a set of components that are communicatively coupled to pass data to and receive data from each other.

FIG. 16 illustrates an example of two paths that are established by eight nets.

FIG. 17 illustrates an example of a reconfigurable IC design that has twenty reconfigurable circuits.

FIG. 18 pictorially illustrates the relationship between the shortest signal transit delay in an IC design and the duration of sub-cycles in a reconfigurable IC.

FIG. 19 illustrates an example of this concurrent optimization for the examples illustrated in FIGS. 14 and 17.

FIG. 20 conceptually illustrates an optimization process that the optimizer of some embodiments performs.

FIG. 21 illustrates an example of computing the normalized metric value for the components of the paths of FIG. 16.

FIG. 22 illustrates two examples of assigning the circuits of two paths to different sub-cycles according to the above-described approach.

FIG. 23 illustrates several state elements that are defined at the sub-cycle boundaries for the examples illustrated in FIG. 22.

FIG. 24 illustrates a move that reassigns a circuit from one sub-cycle to another sub-cycle.

FIG. 25 illustrates how some embodiments define timing constraints that are based on signal delay in a path that is executed in multiple sub-cycles.

FIG. 26 illustrates operational time extension and the use of state elements to perform operational time extension.

FIG. 27 illustrates two sets of signal-delay values through the path of FIG. 26, where one set of values can be rectified.

FIG. 28 illustrates two sets of signal-delay values through the path of FIG. 26, where one set of values cannot be rectified.

FIG. 29 illustrates another set of numerical values for the durations of the operations of the circuits in the example illustrated in FIG. 26.

FIG. 30 illustrates an example of a configurable tile arrangement architecture that is formed by numerous configurable tiles that are arranged in an arrangement with multiple rows and columns.

FIG. 31 illustrates an example of a configurable tile arrangement architecture that is used in some embodiments of the invention.

FIG. 32 illustrates an example of a configurable tile arrangement architecture that is used in some embodiments of the invention.

FIG. 33 illustrates an example of a configurable tile arrangement architecture that is used in some embodiments of the invention.

FIG. 34 illustrates an example of a configurable tile arrangement architecture that is used in some embodiments of the invention.

FIG. 35 illustrates an example of a configurable tile arrangement architecture that is used in some embodiments of the invention.

FIG. 36 illustrates a possible physical architecture of the configurable IC illustrated in FIG. 30.

FIG. 37 presents a timing module of some embodiments for determining whether the timing requirements of the IC design have been satisfied during different steps of the IC design.

FIG. 38 presents a process that extends the operation of a configurable circuit to facilitate placement in some embodiments.

FIG. 39 presents a process that extends the operation of a configurable circuit to facilitate routing.

FIG. 40 illustrates a path in a user design that includes five LUTs.

FIG. 41 conceptually illustrates a pair of LUTs and a set of RMUXs that are used to implement the user design of FIG. 40 in multiple reconfiguration subcycles.

FIG. 42 illustrates the connections (i.e., placement and routing decisions) made between LUTs and RMUXs in reconfiguration cycle 0 of some embodiments to implement a part of path of FIG. 40.

FIG. 43 illustrates the connections (i.e., placement and routing decisions) used for implementing a part of path during configuration cycle 1 of some embodiments.

FIG. 44 illustrates the connections (i.e., placement and routing decisions) used for implementing a part of path during configuration cycles 2 and 3 of some embodiments.

FIG. 45 illustrates one example of extending an operation of configurable logic circuits in some embodiments.

FIG. 46 illustrates a LUT in some embodiments.

FIG. 47 conceptually illustrates a multiplexer that implements the function of the LUT of FIG. 46.

FIG. 48 conceptually illustrates a LUT implemented by a multiplexer in a reconfigurable IC design in some embodiments.

FIG. 49 conceptually illustrates a process that performs timing analysis for a reconfigurable IC design.

FIG. 50 illustrates delay calculation for the path of FIG. 40 by the timing module of some embodiments.

FIG. 51 illustrates extending the operation of a circuit module in the unfolded netlist of FIG. 50 in order to achieve more optimal timing.

FIG. 52 illustrates a time-saving latch extension of some embodiments.

FIG. 53 illustrates a critical path of some embodiments.

FIG. 54 illustrates the critical path of FIG. 53 through the six reconfiguration cycles in some embodiments.

FIG. 55 illustrates a critical path during reconfiguration cycle 0 in some embodiments.

FIG. 56 illustrates a critical path during reconfiguration cycle 1 in some embodiments.

FIG. 57 illustrates a set of LUTs whose operations are extended into other configuration cycles in some embodiments.

FIG. 58 illustrates a set of LUTs whose operations are extended into other configuration cycles in some embodiments.

FIG. 59 shows a worst case scenario in some embodiments in which that every reconfiguration cycle has one LUT whose operation is extended.

FIG. 60 illustrates a more likely scenario that extended paths incur an extra 25% number of reconfigurable circuits in some embodiments.

FIG. 61 illustrates a path in which cycle 1, 3, and 5 start with an RMUX instead of a LUT in some embodiments.

FIG. 62 illustrates a scenario that the operation of the first RMUX has to be extended into cycle 1 in some embodiments.

FIG. 63 shows a LUT that is determined to be extended from cycle 1 into cycle 2 in some embodiments.

FIG. 64 illustrates a scenario in which 3 RMUXs and only two LUTs are extended into next configuration cycles in some embodiments.

FIG. 65 presents a computer system with which one embodiment of the invention is implemented.

DETAILED DESCRIPTION OF THE INVENTION

In the following description, numerous details are set forth for purpose of explanation. However, one of ordinary skill in the art will realize that the invention may be practiced without the use of these specific details. For instance, not all embodiments of the invention need to be practiced with the specific number of bits and/or specific devices (e.g., multiplexers) referred to below. In other instances, well-known structures and devices are shown in block diagram form in order not to obscure the description of the invention with unnecessary detail.

For an IC that has several operational cycles, some embodiments of the invention provide a method that assigns the components in an IC design to different configurable circuits and different operational cycles of the IC. In some embodiments, this method is an optimization process that concurrently optimizes the assignment of the IC-design components to different configurable circuits and different operational cycles of the IC.

Several more detailed embodiments are described below. In these embodiments, the IC is a sub-cycle reconfigurable IC. Accordingly, these embodiments simultaneously optimize the physical design and sub-cycle assignment of a sub-cycle reconfigurable IC. One of ordinary skill will realize that other embodiments are not used for optimizing sub-cycle reconfigurable IC's. For instance, some embodiments are used to optimize simultaneously the physical design and reconfiguration cycle of a reconfigurable IC that does not reconfigure at a sub-cycle basis (i.e., reconfigures at a rate slower than a sub-cycle rate). Before describing these embodiments further, several terms and concepts are defined in Section I.

I. Terms and Concepts

A. Configurable IC

A configurable IC is an IC that has configurable circuits. In some embodiments, a configurable IC includes configurable computational circuit (e.g., configurable logic circuits) and configurable routing circuits for routing the signals to and from the configurable computation units. In addition to configurable circuits, a configurable IC also typically includes non-configurable circuits (e.g., non-configurable logic circuits, interconnect circuits, memories, etc.).

A configurable circuit is a circuit that can “configurably” perform a set of operations. Specifically, a configurable circuit receives “configuration data” that specifies the operation that the configurable circuit has to perform in the set of operations that it can perform. In some embodiments, configuration data is generated outside of the configurable IC. In these embodiments, a set of software tools typically converts a high-level IC design (e.g., a circuit representation or a hardware description language design) into a set of configuration data that can configure the configurable IC (or more accurately, the configurable IC's configurable circuits) to implement the IC design.

Examples of configurable circuits include configurable interconnect circuits and configurable logic circuits. A logic circuit is a circuit that can perform a function on a set of input data that it receives. A configurable logic circuit is a logic circuit that can be configured to perform different functions on its input data set.

FIG. 4 illustrates an example of a configurable logic circuit 400 that can perform a set of functions. As shown in this figure, the logic circuit 400 has a set of input terminals 405, a set of output terminals 410, and a set of configuration terminals 415. The logic circuit 400 receives a set of configuration data along its configuration terminals 415. Based on the configuration data, the logic circuit performs a particular function within its set of functions on the input data that it receives along its input terminals 405. The logic circuit then outputs the result of this function as a set of output data along its output terminal set 410. The logic circuit 400 is said to be configurable as the configuration data set “configures” the logic circuit to perform a particular function.

A configurable interconnect circuit is a circuit that can configurably connect an input set to an output set in a variety of manners. FIG. 5 illustrates an example of a configurable interconnect circuit 500. This interconnect circuit 500 connects a set of input terminals 505 to a set of output terminals 510, based on a set of configuration data 515 that the interconnect circuit receives. In other words, the configuration data specify how the interconnect circuit should connect the input terminal set 505 to the output terminal set 510. The interconnect circuit 500 is said to be configurable as the configuration data set “configures” the interconnect circuit to use a particular connection scheme that connects the input terminal set to the output terminal set in a desired manner.

An interconnect circuit can connect two terminals or pass a signal from one terminal to another by establishing an electrical path between the terminals. Alternatively, an interconnect circuit can establish a connection or pass a signal between two terminals by having the value of a signal that appears at one terminal appear at the other terminal. In connecting two terminals or passing a signal between two terminals, an interconnect circuit in some embodiments might invert the signal (i.e., might have the signal appearing at one terminal inverted by the time it appears at the other terminal). In other words, the interconnect circuit of some embodiments implements a logic inversion operation in conjunction to its connection operation. Other embodiments, however, do not build such an inversion operation in some or all of their interconnect circuits.

B. Circuit and Configurable Node Arrays

A circuit array is an array with several circuit elements that are arranged in several rows and columns. One example of a circuit array is a configurable node array, which is an array where some or all the circuit elements are configurable circuits (e.g., configurable logic and/or interconnect circuits). FIG. 6 illustrates an example of a configurable node array 600 that includes 208 configurable nodes 605 that are arranged in 13 rows and 16 columns. Each configurable node in a configurable node array is a configurable circuit that includes one or more configurable sub-circuits.

In some embodiments, some or all configurable nodes in the array have the same or similar circuit structure. For instance, in some embodiments, some or all the nodes have the exact same circuit elements (e.g., have the same set of logic gates and circuit blocks and/or same interconnect circuits), where one or more of these identical elements are configurable elements. One such example would be a set of nodes positioned in an array, where each node is formed by a particular set of logic and interconnects circuits. Having nodes with the same circuit elements simplifies the process for designing and fabricating the IC, as it allows the same circuit designs and mask patterns to be repetitively used to design and fabricate the IC.

In some embodiments, the similar configurable nodes not only have the same circuit elements but also have the same exact internal wiring between their circuit elements. For instance, in some embodiments, a particular set of logic and interconnects circuits that are wired in a particular manner forms each node in a set of nodes in the array. Having such nodes further simplifies the design and fabrication processes as it further simplifies the design and mask making processes.

In some embodiments, each configurable node in a configurable node array is a simple or complex configurable logic circuit. In some embodiments, each configurable node in a configurable node array is a configurable interconnect circuit. In such an array, a configurable node (i.e., a configurable interconnect circuit) can connect to one or more logic circuits. In turn, such logic circuits in some embodiments might be arranged in terms of another configurable logic-circuit array that is interspersed among the configurable interconnect-circuit array.

Also, some embodiments use a circuit array that includes numerous configurable and non-configurable circuits that are placed in multiple rows and columns. In addition, within the above described circuit arrays and/or configurable node arrays, some embodiments disperse other circuits (e.g., memory blocks, processors, macro blocks, IP blocks, SERDES controllers, clock management units, etc.).

Some embodiments might organize the configurable circuits in an arrangement that does not have all the circuits organized in an array with several aligned rows and columns. Accordingly, instead of referring to configurable circuit arrays, the discussion below refers to configurable circuit arrangements. Some arrangements may have configurable circuits arranged in one or more arrays, while other arrangements may not have the configurable circuits arranged in an array.

C. Reconfigurable IC

Reconfigurable IC's are one type of configurable IC's. Reconfigurable IC's are configurable IC's that can reconfigure during runtime. In other words, a reconfigurable IC is an IC that has reconfigurable logic circuits and/or reconfigurable interconnect circuits, where the reconfigurable logic and/or interconnect circuits are configurable logic and/or interconnect circuits that can “reconfigure” more than once at runtime. A configurable logic or interconnect circuit reconfigures when it receives a different set of configuration data.

FIG. 7 illustrates an example of a reconfigurable logic circuit 700. This logic circuit includes a core logic circuit 705 that can perform a variety of functions on a set of input data 710 that it receives. The core logic circuit 705 also receives a set of four configuration data bits 715 through a switching circuit 720, which in this case is formed by four four-to-one multiplexers 740. The switching circuit receives a larger set of sixteen configuration data bits 725 that, in some cases, are stored in a set of storage elements 730 (e.g., a set of memory cells, such as SRAM cells). This switching circuit is controlled by a two-bit reconfiguration signal φ through two select lines 755. Whenever the reconfiguration signal changes, the switching circuit supplies a different set of four configuration data bits to the core logic circuit 705. The configuration data bits then determine the function that the logic circuit 705 performs on its input data. The core logic circuit 705 then outputs the result of this function on the output terminal set 745.

Any number of known logic circuits (also called logic blocks) can be used in conjunction with the invention. Examples of such known logic circuits include look-up tables (LUT's), universal logic modules (ULM's), sub-ULM's, multiplexers, and PAL/PLA. In addition, logic circuits can be complex logic circuit formed by multiple logic and interconnect circuits. Examples of simple and complex logic circuits can be found in Architecture and CAD for Deep-Submicron FPGAs, Betz, et al., ISBN 0792384601, 1999; and in Design of Interconnection Networks for Programmable Logic, Lemieux, et al., ISBN 1-4020-7700-9, 2003. Other examples of reconfigurable logic circuits are provided in U.S. patent application Ser. No. 10/882,583, entitled “Configurable Circuits, IC's, and Systems,” filed on Jun. 30, 2004. This Application is incorporated in the present application by reference.

FIG. 8 illustrates an example of a reconfigurable interconnect circuit 800. This interconnect circuit includes a core interconnect circuit 805 that connects input data terminals 810 to an output data terminal set 815 based on a configuration data set 820 that it receives from a switching circuit 825, which in this example is formed by two four-to-one multiplexers 840. The switching circuit 825 receives a larger set of configuration data bits 830 that, in some embodiments, are stored in a set of storage elements 835 (e.g., a set of memory cells, such as SRAM cells). This switching circuit is controlled by a two-bit reconfiguration signal φ through two select lines 855. Whenever the reconfiguration signal changes, the switching circuit supplies a different set of two configuration data bits to the core interconnect circuit 805. The configuration data bits then determine the connection scheme that the interconnect circuit 805 uses to connect the input and output terminals 810 and 815.

Any number of known interconnect circuits (also called interconnects or programmable interconnects) can be used in conjunction with the invention. Examples of such interconnect circuits include switch boxes, connection boxes, switching or routing matrices, full- or partial-cross bars, etc. Such interconnects can be implemented using a variety of known techniques and structures. Examples of interconnect circuits can be found in Architecture and CAD for Deep-Submicron FPGAs, Betz, et al., ISBN 0792384601, 1999, and in Design of Interconnection Networks for Programmable Logic, Lemieux, et al., ISBN 1-4020-7700-9, 2003. Other examples of reconfigurable interconnect circuits are provided in the U.S. patent application Ser. No. 10/882,583.

As mentioned above, the logic and interconnect circuits 700 and 800 each receive a reconfiguration signal φ. In some embodiments, this signal is a sub-cycle signal that allows the circuits 700 and 800 to reconfigure on a sub-cycle basis, i.e., to reconfigure one or more times within a cycle of a primary clock. The primary clock might be a design clock for which the user specifies a design. For instance, when the design is a Register Transfer Level (RTL) design, the design clock rate can be the clock rate for which the user specifies his or her design in a hardware description language (HDL), such as VHDL or Verilog. Alternatively, the primary clock might be an interface clock that defines the rate of input to and/or output from the IC (e.g., the rate that the fastest interface circuit of the IC passes signals to and/or receives signals from circuits outside of the IC).

Several novel techniques for distributing reconfiguration signals φ are described in U.S. patent application Ser. No. 11/081,859, entitled “Configurable IC with Interconnect Circuits that also Perform Storage Operations”, which is filed on Mar. 15, 2005. In conjunction with these clock distribution techniques, this application discloses several novel circuits for supplying configuration data to configurable circuits on a sub-cycle basis, based on the distributed clock signals. Content of U.S. patent application Ser. No. 11/081,859 is herein incorporated by reference.

D. Sub-Cycle Reconfigurable IC

FIG. 9 conceptually illustrates an example of a sub-cycle reconfigurable IC. Specifically, in its top left hand corner, this figure illustrates an IC design 905 that operates at a clock speed of X MHz. Typically, an IC design is initially specified in a hardware description language (HDL), and a synthesis operation is used to convert this HDL representation into a circuit representation. After the synthesis operation, the IC design includes numerous electronic circuits, which are referred to below as “components.”

As further illustrated in FIG. 9, the operations performed by the components in the IC design 905 can be partitioned into four sets of operations 910-925, with each set of operations being performed at a clock speed of X MHz. FIG. 9 then illustrates that these four sets of operations 910-925 can be performed by one sub-cycle reconfigurable IC 930 that operates at 4X MHz. In some embodiments, four cycles of the 4X MHz clock correspond to four sub-cycles within a cycle of the X MHz clock. Accordingly, this figure illustrates the reconfigurable IC 930 reconfiguring four times during four cycles of the 4X MHz clock (i.e., during four sub-cycles of the X MHz clock). During each of these reconfigurations (i.e., during each sub-cycle), the reconfigurable IC 930 performs one of the identified four sets of operations. In other words, the faster operational speed of the reconfigurable IC 930 allows this IC to reconfigure four times during each cycle of the X MHz clock, in order to perform the four sets of operations sequentially at a 4X MHz rate instead of performing the four sets of operations in parallel at an X MHz rate.

Sub-cycle configurability has many advantages. One advantage is that it allows a larger, slower IC design to be implemented by a smaller, faster IC design. FIGS. 10-15 present an example that illustrates this benefit. FIG. 10 illustrates a set of Boolean gates that compute two functions G3 and P3 based on a set of inputs A0, B0, A1, B1, A2, and B2. The set of Boolean gates has to compute these two functions based on the received input set in one design cycle. In this example, one design cycle lasts 10 ns, as the design clock's frequency is 100 MHz. However, in this example, each gate can operate at 400 MHz. Hence, each design cycle can be broken down into 4 sub-cycles of 2.5 ns duration, in order to meet the design clock frequency of 100 MHz.

FIG. 11 illustrates the design 1000 of FIG. 10 after its gates have been placed into four groups. These gates have been placed into four groups in order to break down the design 1000 into four separate groups of gates that can be configured and executed in four sub-cycles by a smaller group of gates. The groupings illustrated in FIG. 11 are designed to separate out the computation of different sets of gates while respecting the operational dependencies of other gates. For instance, gates 1005, 1010, and 1015 are defined as a separate group from gates 1020, 1025, and 1030, as these two sets of gates have no operational dependencies (i.e., the output of the gates in one set is not dependent on the output of the gates in the other set). As these two sets of gates have no operational dependencies, one set is selected for computation during the first sub-cycle (i.e., during phase 1), while the other set is selected for computation during the second sub-cycle (i.e., during phase 2). On the other hand, gates 1035, 1040, and 1045 are dependent on the outputs of the first two sets of gates. Hence, they are designated for configuration and execution during the third sub-cycle (i.e., during phase 3). Finally, the gate 1050 is dependent on the output of the first and third sets of gates, and thus it is designated for configuration and execution during the fourth sub-cycle (i.e., during phase 4).

FIG. 12 illustrates another representation of the design 1000 of FIG. 10. Like FIG. 11, the schematic in FIG. 12 illustrates four phases of operation. However, now, each gate in the design 1000 has been replaced by a sub-cycle configurable logic circuit 1205, 1210, or 1215. Also, only three logic circuits 1205, 1210, and 1215 are used in FIG. 12, as each of the gates in FIG. 10 can be implemented by one logic circuit, and the groupings illustrated in FIGS. 11 and 12 require at most three gates to be execute during any given phase. (In FIG. 12, each logic circuit's operation during a particular phase is identified by a superscript; so, for example, reference numbers 1205 ¹, 1205 ², and 1205 ³, respectively, identify the operation of the logic circuit 1205 during phases 1, 2, and 3.)

As shown in FIG. 12, the outputs of certain logic circuits in earlier phases need to be supplied to logic circuit operations in the later phases. Such earlier outputs can be preserved for later computations by using state elements (such as registers or latches). Such state elements (not shown) can be standalone circuits or can be part of one or more interconnect circuits. For instance, in some embodiments, the state elements are storage elements that also (1) are interconnect circuits, (2) are part of interconnect circuits, or (3) are placed within or next to interconnect circuits.

In some of these embodiments, such interconnect circuits are sub-cycle configurable interconnect circuits that are configured to connect the logic circuits in the desired manner. FIG. 13 illustrates a circuit representation of one such storage/interconnect circuit. This circuit 1300 is formed by placing a latch 1305 at the output stage of a multiplexer 1310. The latch 1305 receives a latch enable signal. When the latch enable signal is inactive, the circuit simply acts as an interconnect circuit. On the other hand, when the latch enable signal is active, the circuit acts as a latch that outputs the value that the circuit was previously outputting while serving as an interconnect circuit. Accordingly, when a second circuit in a second later sub-cycle needs to receive the value of a first circuit in a first earlier sub-cycle, the circuit 1300 can be used to receive the value in a sub-cycle before the second later sub-cycle (e.g., in the first earlier sub-cycle) and to latch and output the value to the second circuit in the second later sub-cycle. The circuit 1300 and other storage/interconnect circuits are further described in U.S. Patent Application entitled “Configurable IC with Interconnect Circuits that also Perform Storage Operations”, which is filed concurrently with the present application, with attorney docket number TBUL.P0022. This application is incorporated herein by reference.

FIGS. 10-12 illustrate that sub-cycle configurability allows a ten-gate design that operates at 100 MHz to be implemented by three sub-cycle configurable logic circuits and associated configurable interconnect circuits and state elements that operate at 400 MHz. Even fewer than three logic circuits might be necessary if one logic gate can perform the operation of two or more gates that are executing during each phase illustrated in FIG. 11.

II. Overview

Some embodiments of the invention assign the components in the IC design to different reconfigurable circuits and different sub-cycles of a sub-cycle reconfigurable IC. Some of these embodiments utilize an optimizer that concurrently optimizes the assignment of the IC-design components to different locations (i.e., different physical circuit sites) and different sub-cycles of a sub-cycle reconfigurable IC. Before describing these embodiments, several terms need to be further defined.

A configurable or non-configurable IC design includes numerous circuits (referred to below as design components). For instance, FIG. 14 illustrates an example of an IC design 1400 that includes seventy-two design components 1405. In an IC design, each component lies on one or more signal paths (“paths”). For instance, FIG. 15 illustrates a path through a set of components that are communicatively coupled to pass data to and receive data from each other. As shown in this figure, a path has two endpoints, a source point 1505 and a target point 1510. The source and target designations of the endpoints are based on the direction of the signal flow through the path.

An IC design also includes numerous nets, where each net specifies a set of component terminals that need to be connected (i.e., each net specifies the interconnection of a set of component terminals). For instance, FIG. 16 illustrates an example of two paths 1600 and 1605 that are established by eight nets 1610-1645. Seven nets 1610-1640 establish the path 1600 through user register 1650, components 1652-1662, and user register 1664. Four nets 1610-1620 and 1645 establish the path 1605 through user register 1650, components 1652, 1654, and 1666, and user register 1668. Except net 1620, all nets are two terminal nets (i.e., connect two terminals). Net 1620 is a three terminal net (i.e., connects three terminals).

A reconfigurable IC design includes numerous reconfigurable circuits, where each reconfigurable circuit is at a physical circuit site in the reconfigurable IC design. For instance, FIG. 17 illustrates an example of a reconfigurable IC design 1700 that has twenty reconfigurable circuits 1705. In each sub-cycle, each reconfigurable circuit can be reconfigured to act as a different configured circuit. Each particular configured circuit exists at a particular operational circuit site, which is at a particular physical circuit site in a particular sub-cycle. For example, FIG. 17 illustrates that, in four sub-cycles, the twenty reconfigurable circuits 1705 can serve as eighty configured circuits that are at eighty operational circuit sites.

FIG. 18 pictorially illustrates the relationship between the shortest signal transit delay in an IC design and the duration of sub-cycles in a reconfigurable IC. Specifically, this figure illustrates a set of input registers 1805, a set of output registers 1810, and a collection 1815 of design components between the register sets 1805 and 1810. The collection 1815 of design components perform numerous operations on the data received by the input register set 1805 to produce the data that the design supplies to the output register set 1810. FIG. 18 pictorially illustrates the collection 1815 of design components in terms of a bubble, to pictorially convey a general collection of components.

FIG. 18 also illustrates an arrow 1820 that represents the shortest signal transit for data to propagate from the input register set 1805 to the output register set 1810 through the components 1815. This shortest signal transit can be used (e.g., by the invention's optimizer) to specify a duration for each sub-cycle of the reconfigurable IC that will implement the IC design of FIG. 18. For instance, the duration of each sub-cycle might be specified as 950 ps when the reconfigurable IC has four sub-cycles and the shortest signal transit between the input and output register sets is 5000 ps.

Some embodiments of the invention utilize an optimizer that assigns the components in the IC design to different locations (i.e., different physical circuit sites) and/or different sub-cycles of a sub-cycle reconfigurable IC. In other words, the invention's optimizer optimizes the assignment of IC-design components to different operational circuit sites, where some of the operational circuit sites exist in different sub-cycles. Accordingly, the optimizer concurrently optimizes the physical-location and sub-cycle assignments of the IC-design components.

Assigning a particular IC-design component to a particular operational circuit site that is defined at a particular physical circuit site in a particular sub-cycle, means that the reconfigurable circuit at the particular physical circuit site is configured during the particular sub-cycle to perform the operation of the particular IC-design component (i.e., means that the reconfigurable circuit at the particular physical circuit site is to be assigned a configuration data set during the particular sub-cycle that would configure the reconfigurable circuit to perform the operation of the particular IC-design component).

FIG. 19 illustrates an example of this concurrent optimization for the examples illustrated in FIGS. 14 and 17. FIG. 19 has numerous rows, where each row illustrate a particular assignment of the seventy-two components 1405 in the IC design 1400 of FIG. 14 to seventy-two operational circuit sites of the reconfigurable IC design 1700 of FIG. 17. For instance, the top row 1905 in this figure illustrates an initial assignment of the seventy-two components 1405. As shown in this top row, the initial assignment includes fourteen IC-design components in sub-cycle 1, fifteen IC-design components in sub-cycle 2, fourteen IC-design components in sub-cycle 3, and seventeen IC-design components in sub-cycle 4.

The first row 1905 and the second row 1910 of FIG. 19 illustrate the reassignment 1970 of one of the IC-design components from one operational circuit site within the second sub-cycle to another operational circuit site within the second sub-cycle. Similarly, the second and third rows 1910 and 1915 illustrate the reassignment 1975 of a component from one operational circuit site within the third sub-cycle to another operational circuit site within the third sub-cycle. The movements illustrated between the first and second rows and between the second and third rows are simply movements in the x- and y-locations of the assignments of an IC-design component during a particular sub-cycle.

The invention's optimizer, however, also allows for the reassignment of the operation of an IC-design component to a different sub-cycle. In other words, the invention's optimizer allows for the reassignment of an IC-design component to a different operational circuit site (that can be at the same physical circuit site or at a different physical circuit site) in a different sub-cycle.

FIG. 19 illustrates two examples of such temporal movements. Specifically, the third and fourth rows 1915 and 1920 illustrate the reassigning 1960 of a design component from an operational circuit site in the first sub-cycle to an operational circuit site in the second sub-cycle. This reassignment is simply a reassignment in time as both operational circuit sites are at the same physical circuit site in the reconfigurable IC.

The fourth and fifth rows 1920 and 1925, on the other hand, illustrate an example of a reassignment that is in both time and x-/y-location of the operational circuit sites. Specifically, these two rows illustrate the reassigning 1965 of a component from a first operational circuit site 1930 in the third sub-cycle to a second operational circuit site 1935 in the fourth sub-cycle, where the second operational circuit site is three rows above and three columns to the left of the first operational circuit site.

The fourth and fifth rows 1920 and 1925 also illustrate an example of a move that interchanges the time and x-/y-locations of two components in the IC design. Specifically, this figure illustrates the interchanging 1980 of the position of two components at two operational circuit sites 1940 and 1945 in two different sub-cycles (i.e., the second and third sub-cycles). This interchanging pictorially illustrates the swapping of the sub-cycle and physical-location assignment of two IC-design components that are implemented by two reconfigurable circuits in the reconfigurable IC.

III. Overall Flow of Some Embodiments

FIG. 20 conceptually illustrates an optimization process 2000 that the optimizer of some embodiments performs. The optimization process 2000 assigns the circuits in an IC design to different locations (i.e., different physical circuit sites) and/or different sub-cycles of a sub-cycle reconfigurable IC that will implement the IC design. In other words, this process simultaneously optimizes the physical-location and sub-cycle assignments of the IC-design components within the reconfigurable IC.

In some embodiments, this optimization process is performed by a placer that identifies the physical-location and sub-cycle assignment of the IC-design components. In other embodiments, a combined placer/router tool performs the optimization process 2000 (1) to specify the design component's physical-location and sub-cycle assignments, and simultaneously (2) to specify the interconnections between these circuits (e.g., to specify the interconnect circuits between the assigned design components).

As shown in FIG. 20, the process 2000 initially identifies (at 2005) a starting operational circuit site (i.e., an initial physical location and sub-cycle) for each design component that it has to place. This identification entails assigning an initial sub-cycle for each circuit in each path in the IC design. The initial sub-cycle assignment in some embodiments involves (1) performing a topologic sort of the components based on their positions in their respective paths, and (2) dividing the sorted components between the different sub-cycles based on this sort.

An IC-design component might be on multiple paths. Accordingly, in some embodiments, the topological sort entails computing for each component a topological metric value that accounts for all the paths that contain the particular component. Some embodiments compute the topological metric value for a particular component by (1) identifying the maximum distance D_(MAXSRC) between the particular component to the source point of any path that contains the particular component, (2) identifying the maximum distance D_(MAXTGT) between the particular component to the target point of any path that contains the particular component, and (3) expressing the topological metric value as a normalized distance metric equal to

$\frac{D_{MAXSRC}}{D_{MAXSRC} + D_{MAXTGT}}.$

Different embodiments express distance values (e.g., the distance between a component and a source or target point of a path) differently. For instance, some embodiments express the distance between a particular component and a point in the path (1) in terms of the number of intervening components between the particular component and the point, (2) in terms of the overall signal delay through the intervening components, or (3) in terms of a combination of the number, signal delay, or other attributes of the intervening components.

FIG. 21 illustrates an example of computing the normalized metric value for the components of the paths 1600 and 1605 of FIG. 16. In this example, it is assumed that the components on the paths 1600 and 1605 are not on any other paths. Also, in this example, the distance between a particular component and a source or target point is expressed in terms of the number of components (including the particular component) between the output or input of the particular point and the source or target point. For instance, component 1654 has two components (including itself) between its output and register 1650, whose output is the source point for both paths 1600 and 1605. The component 1654 has five components (including itself) between its input and register 1664, whose input is the target point for path 1600.

For each component, FIG. 21 illustrates (1) the maximum source/target distance between the particular component and a source/target of a path on which the component resides and (2) the normalized distance metric that is computed based on these maximum distance values. For example, the distance between the component 1654 and the target of path 1600 is five, while its distance to the target of path 1605 is two. The maximum distance between the component 1654 and the source point of path 1600 or 1605 is two. Hence, FIG. 21 illustrates that the maximum distance between the component 1654 and the targets of the paths on which the component 1654 resides is five, and the maximum distance between this component and the sources of the paths on which it resides is two. Based on these two values, the normalized distance metric for the component 1654 is 2/7, as illustrated in FIG. 21.

After computing the normalized distance metric for each circuit in the path, the optimizer sorts (at 2005) the circuits in the path according to an ascending order of normalized distance metric values. The process then assigns (at 2005) circuits to different sub-cycles based on this order. For instance, in some embodiments that employ a four sub-cycle reconfigurable IC, the process might assign (1) the first quarter of the circuits with the lowest normalized distance metric values to the first sub-cycle, (2) the second quarter of the circuits with the next lowest normalized distance metric values to the second sub-cycle, (3) the third quarter of the circuits with the next lowest normalized distance metric values to the fourth sub-cycle, and (4) the last quarter of the circuits with the next lowest normalized distance metric values to the fourth sub-cycle.

FIG. 22 illustrates two examples of assigning the circuits of two paths 2200 and 2220 to different sub-cycles according to the above-described approach. In these examples, the first quarter of the IC-design components have a normalized distance metric that is not greater than 0.35, the second quarter of the IC-design components have a normalized distance metric that is not greater than 0.6, the third quarter of the IC-design components have a normalized distance metric that is not greater than 0.85, and the fourth quarter of the IC-design components have a normalized distance metric that is not less than 0.85.

Near each sub-cycle transition between an earlier sub-cycle and a later sub-cycle, the process specifies (at 2005) state elements to maintain the path's state at the end of the earlier sub-cycle for the first circuit in the later sub-cycle. As mentioned above, some embodiments use interconnect/storage circuits as such state elements. FIG. 23 illustrates several state elements 2305 that are defined at the sub-cycle boundaries for the examples illustrated in FIG. 22. In some embodiments, a state element can also be defined behind one or more circuits that are closer to a sub-cycle boundary.

Also, in some cases, the state elements specified at 2005 are state elements that are inserted after the identification (at 2005) of the initial sub-cycle assignment. In other cases, these elements are circuit-path interconnects that operate as interconnects in one sub-cycle, and operate as a storage element in the subsequent sub-cycle. Such could be the case, for instance, in the embodiments that use the process 2000 as part of a placer/router that specifies the physical location and sub-cycle assignment of both logic and interconnect circuits.

After identifying the initial sub-cycle assignment and specifying the state elements at the sub-cycle boundaries, the process 2000 defines (at 2005) an initial location for the circuits (including the state elements) in each path. The initial location for each circuit is a random location. The initial location for each circuit might result in several paths that exceed sub-cycle time allocations in one or more sub-cycles.

After specifying (at 2005) the initial placement, the process 2000 selects (at 2010) a circuit (i.e., a design component or state element) that can be assigned a new physical location and/or a new sub-cycle. After selecting (at 2010) a circuit that can be reassigned in space or in time, the process identifies (at 2015) a potential “move” for the selected circuit. In some embodiments, identifying a potential move entails identifying a new operational circuit site (i.e., a new physical location and/or a new sub-cycle) for the selected circuit. In some cases, the identified new operational circuit site might be associated with another circuit, when it is identified as a new potential circuit site for the selected circuit. Hence, in these cases, the move entails swapping the temporal and/or physical location of the selected circuit with the temporal and/or physical location of another circuit, which has to be a “moveable” circuit in the embodiments that have temporal restrictions on moving circuits.

In some embodiments, the process does not select (at 2015) a potential move that causes the violation of one or more particular timing rules. One example of such a timing rule is a prohibition of some embodiments against allowing a first circuit that is earlier than a second circuit in a path to be placed in a sub-cycle that is later than the currently assigned sub-cycle of the second circuit. Specifically, in some embodiments, the optimization process 2000 cannot always reassign a particular circuit from a first operational circuit site in a first earlier sub-cycle to a second operational circuit site in a second later sub-cycle, when the particular circuit is part of a path that has another circuit that (1) is after the particular circuit in the path, but (2) is before the second sub-cycle.

Instead of, or in conjunction with this timing rule, some embodiments consider at 2015 other timing rules. One example of such a timing rule is a prohibition against two circuits occupying the same operational circuit site. Another example of such a timing rule is a prohibition against exceeding sub-cycle timing constraints with respect to logical depth or delay. Section IV provides several examples of timing constraints relating to overall signal path delay and sub-cycle signal path delay.

Other embodiments, however, do not place such restrictions on reassigning circuits to different sub-cycles. For instance, some embodiments allow a first circuit in a path that is before a second circuit in the path to be placed in a sub-cycle that is after the second circuit's sub-cycle, as these embodiments account for the toroidal nature of sub-cycle reconfiguration. These embodiments might allow a path's earlier circuit to be placed in a second sub-cycle that is after a first sub-cycle that contains the path's later circuit. These embodiments would allow such an assignment as the second sub-cycle in a first primary cycle would be before the first sub-cycle in a second primary cycle that is after the first primary cycle.

However, in some of the embodiments, the optimization process 2000 can make moves that violate one or more timing rules, but penalizes such moves when costing them (at 2020). Penalizing moves are further described below. Some embodiments do not allow moves that violate certain timing rule or rules, while allowing but penalizing moves that violate other timing rule or rules.

Once the process identifies a new physical and/or temporal location for the selected circuit, the process determines (at 2020) whether to assign the newly identified operational circuit site to the selected circuit. In some embodiments, this determination includes computing a cost for the potential new assignment (or assignments in case of a swap) and then making a determination based on this cost whether to accept the new assignment (or assignments).

Three issues need to be considered in performing this computation and determination. The first issue is whether the computed cost expresses a delta cost associated with a potential move, or whether the computed cost expresses the overall cost of the design (e.g., the overall cost of the placement in some embodiments, or the placement and routing in other embodiments). In other words, the computed cost expresses different costs in different embodiments of the invention.

In some embodiments, the computed cost is a delta cost associated with the potential move. In some of these embodiments, this delta cost can be a positive or negative cost, where, in some embodiments, a negative cost implies an improvement in the design (e.g., in a temporal or physical placement and/or routing in the design), while a positive cost implies deterioration in the design.

In other embodiments, the computed cost is the overall cost of the design when the selected circuit is placed at the newly identified operational circuit site, which, as mentioned above, might entail the movement of another circuit to the selected circuit's current operational site. In yet other embodiments, the computed cost expresses a combination of a delta cost and an overall cost.

The second issue is whether the computed cost expressly accounts for a physical-location reassignment, a sub-cycle reassignment, or both. A physical-location reassignment is a reassignment to a new operational circuit site that is at a different physical circuit site than the current operational circuit site of the circuit. Some embodiments compute a cost for a new potential physical location for the selected circuit based on traditional metrics that account for the change in the expected wire length and/or congestion that might result if the selected circuit is moved to the identified operational circuit site (i.e., the site identified at 2015). When this move entails swapping the physical location of the selected circuit with the physical location of another circuit, the cost of the physical-location reassignment accounts for the movement of the other circuit as well (e.g., accounts for the change in the expected wire length and/or congestion due to the movement of the other circuit).

A sub-cycle reassignment is a reassignment of the selected circuit to a new sub-cycle (i.e., from one operational circuit site that is in one sub-cycle to another operational circuit site that is in another sub-cycle). Some embodiments compute a cost for a new sub-cycle assignment based on a metric that accounts for change in the congestion (e.g., for the increase or decrease in the congestion of all the paths or of one or more paths that include the selected circuit) in the current and potentially future sub-cycle of the selected circuit. When the move entails swapping the sub-cycle assignment of the selected circuit with the sub-cycle assignment of another circuit, the cost of the sub-cycle reassignment accounts for the movement of the other circuit as well (e.g., accounts for the change in the expected sub-cycle congestion due to the movement of the other circuit).

Some embodiments do not expressly account for potential sub-cycle reassignments, and instead only expressly account for potential reassignments in physical location. For instance, when costing a move of the selected circuit between two operational circuit sites that occupy the same physical circuit site in two different sub-cycles, some embodiments do not expressly assign a cost for the change, so long as the move does not create a timing violation.

However, even some of these embodiments implicitly account for potential sub-cycle reassignments. For instance, some embodiments do not allow the selected circuit to be moved to a new sub-cycle when such a move would cause a timing violation in one or more sub-cycles. One example of a timing violation would occur when the assignment of the selected circuit to the new sub-cycle would cause the selected circuit's path to exceed the available time period for operation in the new sub-cycle. For instance, assume that the identified move reassigns the fourth circuit 2205 in the first path 2200 in FIG. 22 from the second sub-cycle to the third sub-cycle, as illustrated in parts (a) and (b) of FIG. 24. Such a move might result in a timing violation as the operation of the fourth, fifth, and sixth circuits 2205-2215 of the path 2200 might exceed the allotted time period for the third sub-cycle (e.g., the signal transit through the fourth, fifth, and sixth circuits might take longer than the X number of picoseconds that represents the time period for the third sub-cycle).

On the other hand, whenever feasible, some embodiments allow a move to a new sub-cycle even when such a move causes a path (e.g., a path containing the selected circuit or containing a circuit that swapped with the selected circuit) to exceed the duration of one or more sub-cycles. In some embodiments, the process 2000 allow such moves if the timing violations can be rectified through “retiming,” or can be ameliorated through “operational time extension.”

In certain situations, retiming can rectify a timing violation that occurs when a move causes a path to exceed its duration in one or more sub-cycle. For instance, in some embodiments, retiming assigns one or more circuits from a congested sub-cycle to another sub-cycle to reduce the path's duration in the congested sub-cycle. Part (c) of FIG. 24 illustrates an example of such a retiming. Specifically, this part illustrates the reassignment of the circuit 2215 from the third to the fourth sub-cycle. This retiming reduces the duration of the path 2200 in the third sub-cycle below its assigned sub-cycle duration, and thereby alleviates the over congestion in this path during the third sub-cycle that resulted form the move of the circuit 2205 to the third sub-cycle. As shown in part (c) FIG. 24, the retiming requires the state element 2405 to be placed before the circuit 2215 instead of being placed after this circuit.

It might not always be possible to rectify a timing violation through retiming. In certain situations, the process 2000 can address a timing violation in a sub-cycle through operational time extension, i.e., by allowing the operations of one or more of the circuits to spill over to the previous or subsequent sub-cycles. Such time-extension moves might not always be possible, but whenever such moves are possible, they are penalized in some embodiments in order to bias the optimizer not to make too many of such moves. Accordingly, instead of prohibiting sub-cycle reassignments that result in the operations of the circuits in a path to exceed the duration(s) of one or more sub-cycles, some embodiments allow the optimization process 2000 to consider such reassignments whenever possible but require the process to assess a penalty cost for making such a reassignment. Operational time extension will be further described below in Section V.

It should be noted that timing violations might occur even when the identified move is within the same sub-cycle (i.e., even when the identified move is between two operational circuit sites in the same sub-cycle). For instance, a physical location reassignment of the selected circuit might result in the operations of the circuits in a path to exceed the duration(s) of one or more sub-cycles. Again, some embodiments prohibit such timing violations, while other embodiments allow such timing violations so long as they can be rectified through retiming or operational time extension, which is penalized as mentioned above.

The third issue to consider in performing the computation and determination operations at 2020 is how the determination is made once the cost is computed. How this determination is made is dependent on the type of optimization technique used to perform the operations of the process 2000. For instance, some optimization techniques (e.g., local optimization) only accept moves that improve the computed cost (e.g., only accept moves that have negative delta cost or reduce the overall cost). Other optimization techniques (e.g., simulated annealing) accept moves that increase the computed cost, but accept fewer such worse moves over time.

When the process 2000 determines (at 2020) that the operation circuit site identified at 2015 should be accepted, the process transitions to 2025, where it moves the selected circuit to the newly identified operational circuit site. When the move identified at 2015 entails swapping the physical location and/or sub-cycle assignment of the selected circuit with the physical location and/or sub-cycle assignment of another circuit, the process 2000 swaps the physical location and/or sub-cycle assignments of the two circuits. From 2025, the process transitions to 2030. The process also transitions to 2030, when it determines that the newly identified operational circuit site should not be accepted for the selected circuit.

At 2030, the process determines whether it should stop its iterations. Again, how this determination is made is dependent on the type of optimization technique used to perform the operations of the process 2000. For instance, some embodiments stop the iterations after failing to improve the computed cost by an acceptable threshold after certain number of failed iterations. In some embodiments, the acceptable threshold and number of failed iterations changes over time (i.e., changes with the number of iterations).

If the process determines (at 2030) that it should not stop, it returns to 2010 to select another circuit for moving, and then repeats the subsequent operations 2015-2030 for the newly selected circuit. When the process determines (at 2030) that it should stop the iterations, it ends.

The invention's optimization process was described above by reference to the optimization process 2000, which sets out one particular way of performing the optimization. One of ordinary skill will realize that the optimization process is performed differently in other embodiments of the invention. For instance, instead of selecting one circuit to move each time at 2010, some embodiments select one or more circuits to move at each iteration through 2010. Also, the process 2000 first computes a score based on an identified move and then moves the selected circuit based on the computed score. Other embodiments, however, might first move the selected circuit, then compute a score to assess the move, and then move the selected circuit back to its original operational circuit site after an assessment that the move should not have been made.

IV. Timing Constraints

FIG. 25 illustrates how some embodiments define timing constraints that are based on signal delay in a path that is executed in multiple sub-cycles. In some embodiments, the optimizer examines these timing constraints for a path each time that it tries to move one or more of the circuits on the path.

FIG. 25 illustrates a path 2500 between two registers 2505 and 2510. This path is implemented in four sub-cycles that are enabled by the three state elements 2515, 2520, and 2525, which maintain the signal at the sub-cycle boundaries. In this example, the three state elements are each an interconnect/storage element 1300 of FIG. 13. This element can operate as an interconnect or as a latch. As such, each element 2515, 2520, or 2525 will be referred to below as a latch.

Each latch 2515, 2520, or 2525 operates in two sub-cycles (e.g., when the latch is an interconnect/storage element, the latch operates as an interconnect element in one sub-cycle and a storage element in another sub-cycle, as mentioned above). However, FIG. 25 illustrates the sub-cycle boundary after the latch because, in this example, the sub-cycles are defined to start at the input of a circuit after a latch. Other embodiments, however, might define the sub-cycle boundary differently.

Ten timing constraints are illustrated in FIG. 25. These ten timing constraints include four single sub-cycle constraints 2530, 2532, 2534, and 2536. They also include six constraints for six contiguously neighboring sets of sub-cycles. These six constraints are (1) three double sub-cycle constraints 2538, 2540, and 2542, (2) two triple sub-cycle constraints 2544 and 2546, and (3) a quadruple sub-cycle constraint 2548.

Each single sub-cycle constraint requires the sub-cycle's duration to be less than the duration allotted to the sub-cycle. As mentioned above, each sub-cycle starts from the first circuit in the sub-cycle, excluding any latch that facilitates the path signal flow during the sub-cycle. Each sub-cycle except the last ends at the start of the latch that facilitates the next sub-cycle, while the last sub-cycle ends at the input of the circuit that is the path's destination.

Similarly, each double, triple, or quadruple sub-cycle constraint requires the duration of the two, three, or four sub-cycles to be less than the duration allotted to the two, three, or four sub-cycles. The start of each two, three, or four sub-cycles is the first circuit in the two, three, or four sub-cycles, excluding any latch that facilitates the path signal flow during the first sub-cycle in the set of sub-cycles. Each sub-cycle set that does not include the last sub-cycle ends at the start of the latch that facilitates the next sub-cycle, while any sub-cycle set that terminates the last sub-cycle ends at the input of the circuit that is the path's destination.

Accordingly, these rules define the following durations for the sub-cycles or the contiguously neighboring sub-cycle sets in FIG. 25:

-   -   Duration of sub-cycle 1 is measured (for the timing constraint         2530) from the start of the register 2505 to the input of the         latch 2515.     -   Duration of sub-cycle 2 is measured (for the timing constraint         2532) from the start of the circuit 2550 to the input of the         latch 2520.     -   Duration of sub-cycle 3 is measured (for the timing constraint         2534) from the start of the circuit 2552 to the input of the         latch 2525.     -   Duration of sub-cycle 4 is measured (for the timing constraint         2536) from the start of the register 2554 to the input of the         register 2510.     -   Duration of neighboring sub-cycles 1 and 2 is measured (for the         timing constraint 2538) from the start of the register 2505 to         the input of the latch 2520.     -   Duration of neighboring sub-cycles 2 and 3 is measured (for the         timing constraint 2540) from the start of the circuit 2550 to         the input of the 2525.     -   Duration of neighboring sub-cycles 3 and 4 is measured (for the         timing constraint 2542) from the start of the circuit 2552 to         the input of the register 2510.     -   Duration of neighboring sub-cycles 1, 2, and 3 is measured (for         the timing constraint 2544) from the start of the register 2505         to the input of the latch 2525.     -   Duration of neighboring sub-cycles 2, 3, and 4 is measured (for         the timing constraint 2546) from the start of the circuit 2550         to the input of the register 2510.     -   Duration of neighboring sub-cycles 1, 2, 3, and 4 is measured         (for the timing constraint 2548) from the start of the register         2505 to the input of the register 2510.

The path 2500 is legal from a timing point of view when it does not violate any of the ten timing constraints. If the path 2500 cannot meet the timing constraint that is defined over the entire path (i.e., overall-path timing constraint, which in this case is the quadruple sub-cycle constraint 2548), then it cannot be made legal through retiming or operational time extension. When the path meets the overall-path timing constraint 2548 (i.e., when the duration of the neighboring sub-cycles 1, 2, 3, and 4 is less than the sum of the four sub-cycle durations), it might not meet one of the other sub-cycle or sub-cycle set constraints. However, in this situation, it might be possible to make the path legal through retiming, and it will be possible to make the path legal through time extension, as further described below.

The examples above and below discuss optimizing a four sub-cycle design. Other embodiments, however, might include some other number of reconfiguration sub-cycles, like six or eight. Using the guidelines provided above, these embodiments have a different number of signal delay timing constraints. Assuming that a path has at least one circuit in each sub-cycle that needs to be reconfigured in that sub-cycle, the path in a six sub-cycle embodiment would have to satisfy: 1 six sub-cycle constraint, 2 five sub-cycle constraints, 3 four sub-cycle constraints, 4 three sub-cycle constraints, 5 two sub-cycle constraints, and 6 single sub-cycle constraints. Assuming that a path has at least one circuit in each sub-cycle that needs to be reconfigured in that sub-cycle, the path in an eight sub-cycle embodiment would have to satisfy: 1 eight sub-cycle constraints, 2 seven sub-cycle constraints, 3 six sub-cycle constraints, 4 five sub-cycle constraints, 5 four sub-cycle constraints, 6 three sub-cycle constraints, 7 two sub-cycle constraints, and 8 single sub-cycle constraints. In addition, other embodiments might define the signal delay timing constraints differently, or define the sub-cycle or the sub-cycle set durations differently.

V. Operational Time Extension

As mentioned above, some embodiments allow the operation of a circuit that is assigned to one sub-cycle to start or end in another sub-cycle. In other words, these embodiments allow the circuit to time extend in one or more sub-cycles that are before and/or after the circuit's assigned sub-cycle. The optimizer of some embodiments penalizes each move that will cause the duration of the operation of the circuits assigned to one sub-cycle to exceed the sub-cycle's duration. The optimizer penalizes such moves as these moves reduce the overall reconfigurable nature of the reconfigurable IC. They reduce the IC's reconfigurability by having one circuit operate in more than one sub-cycle, which reduces the number of operational circuit sites for the other circuits in the design.

In some embodiments, operational time extension is enabled through the use of state elements that can maintain their states (e.g., can store a value). Such state elements maintain the input of the time-borrowing circuit in the sub-cycle or sub-cycles that the circuit borrows. In the examples described below, this state element is the interconnect/storage element 1300 of FIG. 13. This element can operate as an interconnect or as a latch. As such, this element will be referred to below as a latch.

FIG. 26 provides an example that illustrates operational time extension and the use of latches to perform operational time extension. Specifically, this figure illustrates a path 2600 between two user registers 2665 and 2670. The path 2600 includes twelve circuits. As shown in part (a) of FIG. 26, the operation of these circuits is initially divided into four sub-cycles, with three circuits in each sub-cycle. As shown in part (a) of FIG. 26, three of the twelve circuits are latches 2615, 2630, and 2645 that are defined at the sub-cycle boundaries. The latches 2615, 2630, and 2645 are defined from the start to extend their operation from one sub-cycle to the next (i.e., to receive data in one sub-cycle and latch and hold the received data in the next sub-cycle).

Parts (a) and (b) of FIG. 26 illustrate reassignment of the circuit 2625 from the second sub-cycle to the third sub-cycle. As shown in part (b) of FIG. 26, this reassignment moves the latch 2630 from the front of the circuit 2625 to back of the circuit 2625. This reassignment also leads to the time period for the third sub-cycle terminating before the operation of the circuit 2640 has been completed.

Accordingly, to solve this short fall, the circuit 2640 is assigned to both the third and fourth sub-cycles, as shown in part (c) of FIG. 26. The latch 2640 is moved from in front of the circuit 2645 to behind the circuit 2645, as this new position is needed to facilitate the transition between the third and fourth sub-cycles. In this position, the interconnect/storage circuit 2645 acts during the third sub-cycle as an interconnect circuit that passes the signal from the circuit 2635 to the circuit 2640, while acting during the fourth sub-cycle as a latch that outputs the value that the interconnect circuit 2645 was outputting during the third sub-cycle. In other words, the interconnect circuit 2645 acts as a storage element in the fourth sub-cycle in order to provide the circuit 2640 with the same input during the third and fourth sub-cycle, so that the circuit 2640 can complete its operation during the fourth sub-cycle along with the circuits 2650, 2655, and 2660.

In the example illustrated in FIG. 26, the circuit 2645 is an interconnect/storage circuit that is moved after the optimizer identifies the move for the circuit 2625. When this interconnect/storage circuit is moved from the front to the back of the circuit 2640, it might be moved from one physical circuit site to another physical circuit site, or it might be at the same physical circuit site but defined to receive the output of the circuit 2635 instead of the output of the circuit 2640.

More generally, after identifying a move, the optimization process 2000 might determine that the move results in the operation of a path violating one or more signal delay timing constraints over one or more sections of the path. The optimization process 2000 then will try to address the timing constraint violation through retiming or time extensions. Both retiming and time extension involve shorting a section of the path that does not meet one or more timing constraint, by moving the latch at the end of the section back in the path. Moving the latch back in the path reduces the length of the section of the path (behind the latch) that does not meet one or more timing constraints. This move, however, expands the duration of the path in front of the latch that is moved back.

Both retiming and time extension require a latch to be moved in the path. In some embodiments, retiming can be performed by moving the latch backwards or forwards in a path, while time extension only allows the latch to be moved back in the path. Another difference between retiming and time extension is that in retiming, the latch commences its storage operation (e.g., its latching operation) at a boundary between two sub-cycles, while in time extension, the latch commences its storage operation (e.g., its latching operation) behind one or more circuits that commence their operations in the earlier of the two sub-cycles.

A retiming move still needs to result in a path that meets all single and multi sub-cycle constraints. A time-extension move also needs to result in a path that meets all applicable single and multi sub-cycle constraints, except that the time extending circuits are not taken into consideration when considering one or more of the constraints. Specifically, when considering a time-extension move of a particular latch that is between a first earlier sub-cycle and a second later sub-cycle, all timing constraints that relate to durations that end with the particular latch have to be met. Also, the time-extension move has to meet all timing constraints that are measured starting at the first circuit after the last time extending circuit (i.e., starting at the first circuit of the second sub-cycle). In addition, the time-extension move has to meet all timing constraints that are measured starting at the first circuit of the first sub-cycle and ending with the latch or register at the end of the second sub-cycle.

In some embodiments, time extensions might result in the elimination of one or more timing constraints, except the overall-path timing constraint. Specifically, when considering a time-extension move of a first latch that is between a first earlier sub-cycle and a second later sub-cycle, one possible move would be to move the latch behind all of the circuits that are to operate in an first earlier sub-cycle. When the optimization process 2000 is left with only such a move, the process considers eliminating the latch between the earlier and later sub-cycles and having all the circuits in the earlier sub-cycle time extend into (i.e., also operate in) the later sub-cycle. This time extension possibility would rely on a second latch that is between the first earlier sub-cycle and a third sub-cycle that is before the first earlier sub-cycle. This time extension possibility effectively eliminates the timing constraints that were defined with respect to the eliminated latch. Also, if this time extension does not lead to a path that meets the timing constraints, the process 2000 can explore moving the second latch back in the third sub-cycle.

Alternatively, when a time extension operation results in a first latch being moved backward to abut a second prior latch in a particular path, some embodiments do not eliminate the first latch or the timing constraints that were defined by reference to the first latch. These embodiments maintain such a first latch to simplify the timing analysis of the particular path during any move of this path's circuits, which might later be identified by the optimizer. Also, the timing constraints that are defined by reference to the first latch remain after the move that abuts the first and second latch, although these timing constraints would mostly be perfunctory as there is no duration or little duration defined between the two latches, in some embodiments.

Timing extension and retiming will now be further described by providing different signal delay values for the path 2600 of FIG. 26. In the previous discussion of this example, it was assumed that time extending the operation of the circuit 2640 to the fourth sub-cycle allows the signal to pass through the path 2600 within the allotted time. However, in certain situations, this might not be the case. To illustrate this, FIGS. 27 and 28 present two sets of signal-delay values through the path 2600 of FIG. 26. One set of values (the ones provided in FIG. 27) can be rectified through time extending the operation of the circuit 2640, while the other set of values (the ones provided in FIG. 28) cannot. In both these examples, it is assumed that the signal has to pass through the path 2600 in 4000 picoseconds (ps), and that each sub-cycle is 1000 ps long.

In the example illustrated in FIG. 27, the actual duration of operation of the circuits in each sub-cycle before the move is 700 ps, as shown in part (a) of this figure. Given this operational duration, FIG. 27 illustrates an example where the timing violation caused by the reassignment of the circuit 2625 (to the third sub-cycle) can be alleviated through operational time extension. Specifically, part (b) of FIG. 27 illustrates that the duration of the third sub-cycle is 1050 ps after the assignment of the circuit 2625 to this sub-cycle. However, part (c) of FIG. 27 illustrates that allowing the circuit 2640 to time extend into the fourth sub-cycle, leads to a signal flow that meets all three constraints that are at issue at the boundary of the third and fourth sub-cycles. Specifically, time extending the operation of the circuit 2640 results in:

-   -   1. a combined signal path delay of 1750 ps from the input of         circuit 2625 to the input of the user register 2670 (i.e., a         duration of 1750 ps for the circuits operating in the third and         fourth sub-cycles), which does not exceed the 2000 ps allotted         for the third and fourth sub-cycles;     -   2. a signal path delay that does not exceed 1000 ps from the         input of the circuit 2625 to the input of the latch 2645 (i.e.,         a duration that does not exceed 1000 ps for the operations of         the circuits in the third sub-cycle before the latch 2645);     -   3. a signal path delay that does not exceed 1000 ps from the         input of the circuit 2650 (which is the first circuit after the         last time extending circuit 2640) to the input of the user         register 2670.

In the example illustrated in FIG. 28, the actual duration of operation of the circuits in each sub-cycle before the move is 900 ps, as shown in part (a) of this figure. Given this operational duration, FIG. 28 illustrates an example where the timing violation caused by the reassignment of the circuit 2625 (to the third sub-cycle) is not alleviated through one operational time extension. Specifically, part (b) of FIG. 28 illustrates that the duration of the third sub-cycle is 950 ps after the assignment of the circuit 2625 to this sub-cycle. Moreover, part (c) of FIG. 28 illustrates that even with the circuit 2640 time extending into the fourth sub-cycle, the combined duration of the third and fourth sub-cycles is 2150 ps, which is more than the available 2000 ps for these two sub-cycles. However, this situation might be alleviated through other time extension (e.g., potentially moving latch 2630 behind 2620, which would result in time extending across more than one sub-cycle).

Time extensions are useful in addressing time violations that cannot be fixed through retiming. To illustrate this, FIG. 29 presents another set of numerical values for the durations of the operations of the circuits in the example illustrated in FIG. 26. Part (a) of FIG. 29 illustrates that the duration of the operation of the circuits in the first, second and fourth sub-cycles are 900 ps each, while the duration of the operation of the circuits in the third sub-cycle is 1100 ps, which exceeds the 1000 ps allotment. In other words, part (a) shows that the path initially has a timing violation in sub-cycle 3.

Part (b) of this figure illustrates that this timing violation cannot be cured through retiming. Specifically, it illustrates that moving the operation of the circuit 2640 to the fourth sub-cycle creates a timing violation in the fourth sub-cycle (i.e., it causes the duration of the operation of the circuits in the fourth sub-cycle to be 900 ps, which exceeds the 1000 ps allotment).

However, the timing violation illustrated in part (a) of FIG. 29 can be addressed through time extending the operation of the circuit 2640 into the fourth sub-cycle, as shown in part (c) of this figure. This time extension is achieved by moving the circuit 2645 behind the circuit 2640. This move creates a path that meets the constraints mentioned above. Specifically, it results in:

-   -   1. a combined signal path delay of 2000 ps from the input of the         circuit 2635 to the input of the user register 2670 (i.e., a         duration of 2000 ps for the circuits operating in the third and         fourth sub-cycles), which does not exceed the 2000 ps allotted         for the third and fourth sub-cycles;     -   2. a signal path delay of 400 ps from the input of the circuit         2635 to the input of the latch 2645 (i.e., a duration of 400 ps         for the operations of the circuits in the third sub-cycle before         the latch 2645);     -   3. a signal path delay of 900 ps from the input of the circuit         2650 (which is the first circuit after the last time extending         circuit 2640) to the input of the user register 2670.

In the description above, the latch (e.g., latch 2645) that facilitates the time extension can be viewed as one of the time extending circuits. Whether the latch is one of the time extending circuits is an issue of nomenclature in the cases where the latch is moved from a sub-cycle boundary to a position behind the maintained circuits that are time extended. This is because in this situation the latch (e.g., latch 2645) would have operated in the third and fourth sub-cycles even had it not been moved from the boundary of these two sub-cycles.

Although time extension was described above by reference to numerous details, one of ordinary skill will realize that other embodiments might perform time extensions differently. For instance, as mentioned above, some embodiments perform the optimization process 2000 as part of a routing operation that defines interconnect circuits (i.e., a routing circuit) for connecting the various circuits of a path that was placed previously to the routing operation or is being concurrently placed with the routing operation. In such embodiments, the process can facilitate time extensions by moving a latch from a sub-cycle boundary to the back of the maintained circuit(s).

Alternatively, if one of the circuits behind the maintained circuit(s) is an interconnect circuit, the process can also use this interconnect circuit as the latch that facilitates the time extension when this circuit is an interconnect/storage circuit. When this interconnect circuit is not an interconnect/storage circuit, the process can also replace this interconnect circuit with an interconnect/storage circuit that serves as a latch that facilitates the time extension. In these embodiments, whether the optimization process supports the time extension by moving a latch from a sub-cycle boundary or utilizing an interconnect/storage circuit before maintained circuit(s) depends on one or more factors, such as (1) the proximity of the interconnect/storage circuit from the maintained circuit(s), (2) the delay due to an extra latch that might be avoided by reusing an available interconnect/storage circuit, etc.

VI. Reconfigurable Architectures

FIGS. 30-35 illustrate an example of a configurable tile arrangement architecture that is used in some embodiments of the invention. As shown in FIG. 30, this architecture is formed by numerous configurable tiles 3005 that are arranged in an array with multiple rows and columns. In FIGS. 30-35, each configurable tile includes a sub-cycle reconfigurable three-input look up table (LUT) 3010, three sub-cycle reconfigurable input-select multiplexers (IMUXs) 3015, 3020, and 3025, and two sub-cycle reconfigurable routing multiplexers (RMUXs) 3030 and 3035. Other configurable tiles can include other types of circuits, such as memory arrays instead of logic circuits.

In FIGS. 30-35, an input-select multiplexer is an interconnect circuit associated with the LUT 3010 that is in the same tile as the input select multiplexer. One such input select multiplexer receives several input signals for its associated LUT and passes one of these input signals to its associated LUT.

In FIGS. 30-35, a routing multiplexer is an interconnect circuit that at a macro level connects other logic and/or interconnect circuits. In other words, unlike an input select multiplexer in these figures that only provides its output to a single logic circuit (i.e., that only has a fan out of one), a routing multiplexer in some embodiments either provides its output to several logic and/or interconnect circuits (i.e., has a fan out greater than one), or provides its output to other interconnect circuits.

FIGS. 31-35 illustrate the connection scheme used to connect the multiplexers of one tile with the LUT's and multiplexers of other tiles. This connection scheme is further described in U.S. Patent Application entitled “Configurable IC with Routing Circuits with Offset Connections”, filed concurrently with this application with attorney docket number TBUL.P0036. This application is incorporated herein by reference.

In the architecture illustrated in FIGS. 30-35, each tile includes one three-input LUT, three input-select multiplexers, and two routing multiplexers. Other embodiments, however, might have a different number of LUT's in each tile, a different number of inputs for each LUT, a different number of input-select multiplexers, and/or a different number of routing multiplexers. For instance, some embodiments might employ an architecture that has in each tile: one three-input LUT, three input-select multiplexers, and eight routing multiplexers. Several such architectures are further described in the above-incorporated patent application.

In some embodiments, the examples illustrated in FIGS. 30-35 represent the actual physical architecture of a configurable IC. However, in other embodiments, the examples illustrated in FIGS. 30-35 topologically illustrate the architecture of a configurable IC (i.e., they show connections between circuits in the configurable IC, without specifying (1) a particular geometric layout for the wire segments that establish the connection, or even (2) a particular position of the circuits). In some embodiments, the position and orientation of the circuits in the actual physical architecture of a configurable IC is different than the position and orientation of the circuits in the topological architecture of the configurable IC. Accordingly, in these embodiments, the IC's physical architecture appears quite different than its topological architecture. For example, FIG. 36 provides one possible physical architecture of the configurable IC 3000 illustrated in FIG. 30. This and other architectures are further described in the above-incorporated patent application.

VII. Extending Operation of Configurable Circuits to Meet Timing Requirements

Some embodiments provide a sub-cycle timing module (timing engine) that takes into account the reconfiguration cycle of a reconfigurable IC design. The timing module determines whether each reconfiguration cycle of a reconfigurable IC design meets the IC design timing requirements. The sub-cycle timing module is utilized by different Electronic Design Automation (EDA) tools during the IC design. For instance, as shown in FIG. 37, the synthesis engine 3710, placer 3720, router 3730, and verification tool 3740 can use the timing module 3750 to determine whether the timing requirements of the IC design have been satisfied during different steps of the IC design.

In some embodiments, the EDA tools extend the operation of one or more configurable circuits across multiple reconfiguration cycles to meet timing requirements. The configurable circuits can be configurable logic circuits and/or configurable interconnect circuits. The operation of a configurable circuit can be extended into the next reconfiguration cycle, across multiple reconfiguration cycles, or into an earlier reconfiguration cycle. Examples of each type of extension are further described below.

FIG. 52 illustrates a time-saving latch extension of some embodiments. FIG. 52 illustrates LUTs 5205, 5210, 5215, and 5220, as well as time via 5225 and RMUX 5230, along a path. FIG. 52 illustrates these components in two paths, 5235 and 5240. In both paths, dashed line 5245 illustrates the divide between reconfiguration cycle 0, which includes LUTs 5205 and 5210, and reconfiguration cycle 1, which includes LUTs 5215 and 5220. This means that LUT 5205 receives a configuration data set corresponding to operation A (or A′ in path 5235) during reconfiguration cycle 0, LUT 5210 receives a configuration data set corresponding to operation B (or B′) during reconfiguration cycle 0, and so on.

Based on dashed line 5245, RMUX 5230 is in reconfiguration cycle 1 in path 5235. Accordingly, the signal flowing through path 5235 cannot go to the RMUX 5230 until the start of reconfiguration cycle 1 (as shown, the signal starts reconfiguration cycle 1 at 5250 from time via 5225). However, as illustrated in path 5240, reconfiguration cycle 0 includes enough time for a signal traveling along the path to get to the RMUX 5230 before the start of reconfiguration cycle 1. This means that the time represented by the distance from the time via 5225 (i.e., dashed line 5250) to dashed line 5255 is being wasted in path 5235.

Path 5240, the path used by some embodiments, eliminates this wasted time by extending the operation of RMUX 5230 backwards into reconfiguration cycle 0. In other words, RMUX 5230 receives the same configuration data set in both reconfiguration cycle 0 and reconfiguration cycle 1. Therefore, the signal starts reconfiguration cycle 0 from the RMUX 5230 instead of time via 5225. Extending RMUX 5230 backwards into reconfiguration cycle 0 provides a tradeoff of space (the RMUX is used in two reconfiguration cycles) in favor of time (the time represented by the distance from dashed line 5250 to dashed line 5255).

FIG. 38 presents a process 3800 that extends the operation of a configurable circuit to facilitate placement in some embodiments. The process receives (at 3810) an IC design specified by one or more netlists from an EDA tool (e.g., a synthesis tool). The process then identifies (at 3820) a placement decision. In some embodiments, a placement decision is identified when a new location is specified for circuit modules of the netlist or a new location is specified for previously placed circuit modules. Some of these circuit modules include configurable circuits where a configurable circuit can be a configurable logic circuit or a configurable interconnect circuit. Therefore, as part of identifying (at 3820) the placement decision, some embodiments of the process extend the operation of a configurable circuit from one reconfigurable cycle into other reconfigurable cycles.

After identifying the placement decision (at 3820), the process determines (at 3830) if other placements for other previously placed circuit modules have to be made. For instance, such a situation may arise as a result of extending the operation of a configurable circuit into different reconfiguration cycles necessitating the extension of other configurable circuits. If other placements must be made, the process performs the additional placement decisions (at 3820) where the operation of additional configurable circuits may be extended. Otherwise, the process costs (at 3840) the placement decision to determine whether to accept (at 3850) the placement decision.

The process accepts the placement decision when the placement decision satisfies one or more placement constraints (e.g., congestion goals) or if it is determined that the placement decision is more optimal than a previously selected placement decision. For instance, even though a first placement decision satisfies placement constraints, a second placement decision that also satisfies the placement constraints but by occupying fewer physical resources is thus more optimal.

If the process accepts (at 3850) the placement decision, then the process determines (at 3860) whether to make additional placement designs. If the process does not accept (at 3850) the placement decision, the process then reverts (at 3870) back to a previous placement solution and determines (at 3860) whether to continue iterating to make additional placement decisions. If the process is to continue iterating, then the process reverts back to step 3820. Otherwise, the process terminates.

Extending the operation of configurable circuits is explained below by using an example. The example is given using RMUXs. However, the invention can be implemented by using other configurable circuits and/or storage elements. Example of storage elements are described in U.S. patent application Ser. No. 11/754,299, entitled “Configurable IC Having a Routing Fabric with Storage Elements”, filed on May 27, 2007. The content of U.S. patent application Ser. No. 11/754,299 is hereby incorporated by reference. Also, the example is given for extending the operation of an interconnect circuit (such as RMUX). However, a person of ordinary skill in the art would be able to apply the teaching of the invention to extend the operation of a logic circuit (such as a LUT) using similar techniques.

FIG. 39 presents a process 3900 that extends the operation of a configurable circuit to facilitate routing. The process 3900 begins by receiving (at 3910) an IC design specified by one or more netlists from an EDA tool (e.g., a placement tool). The process then identifies (at 3920) a routing decision. In some embodiments, a routing decision is identified when connecting circuit modules after placement or when extending the operation of one or more configurable circuits in order to meet timing requirements. As noted above, the configurable circuits can be configurable logic circuits and/or configurable interconnect circuits.

After identifying the routing decision (at 3920), the process calls (at 3930) a local placer to identify a local placement and define new routes for the routing decision and for those circuit modules affected by the routing decision. For example, by extending the operation of one or more configurable circuits, the timing of one or more other circuit modules may be adversely or beneficially affected. The process costs (at 3940) the routing decision to determine whether to accept (at 3950) the placement decision. The process accepts (at 3950) the routing decision when the routing decision satisfies one or more routing constraints (e.g., timing constraints) or if it is determined that the routing decision is more optimal than a previously selected routing decision.

If the process accepts (at 3950) the routing decision, then the process determines (at 3960) whether to continue iterating to make alternative routing decisions. If the process does not accept (at 3950) the routing decision, the process then reverts (at 3970) back to a previous routing solution and determines (at 3960) whether to continue iterating to make alternative routing decisions. If the process is to continue iterating, then the process reverts back to step 3920. Otherwise, the process terminates.

FIG. 40 illustrates a path 4000 in a user design that includes five LUTs 4005-4025. The overall logical operation performed by the LUTs are identified as L1-L5 where each LUT 4005-4025 performs a portion of the overall logic operation in FIG. 40. In this example, the path starts from the primary input PI and ends at output PO. FIG. 41 conceptually illustrates a pair of LUTs 4105 and a set of RMUXs 4110 that are used to implement the user design of FIG. 40 in multiple reconfiguration subcycles. In this particular example, the reconfigurable IC design has four reconfiguration cycles, (identified by their corresponding cycle numbers on the left most side of FIG. 41). The path 4000 is implemented by using a maximum of two LUTs and three RMUXs in each reconfiguration cycle. For simplicity, all RMUXs are assumed to be interconnect/storage elements such as the interconnect storage element 1300 shown in FIG. 13. These LUTs and RMUXs can be the same or different physical LUTs and RMUXs on each reconfiguration cycle unless the operation of the same LUT of RMUX is extended. These LUTs and RMUXs can be the same or different physical LUTs and RMUXs on each reconfiguration cycle unless the operation of the same LUT of RMUX is extended in which case the operation is preserved while extending the functionality into the next sub-cycle.

FIG. 42 illustrates the connections (i.e., placement and routing decisions) made between the LUTs and RMUXs in reconfiguration cycle 0 of some embodiments to implement a part of path 4000. The connections for other configuration cycles are not shown in FIG. 42 for simplicity. Depending on the EDA tool implementing the design, connections for the other configuration cycles can be already made or the connections for other configuration cycles may not have been determined yet. As shown in FIG. 42, the first LUT receives the primary input PI and implements logic function L1. For simplicity, the LUTs are hereinafter referred to by the functions they implement. As shown, the output of L1 is connected to the input of L2 through RMUX R1.

In this particular example, the output of L2 (which is also generated in configuration cycle 0) has to be available at the input of L3 in configuration cycle 1. As shown, the output of L2 is connected to RMUX 2. Since RMUX 2 has to hold the value of the output of L2 until the beginning of configuration cycle 1, RMUX 2 operates as a latch. The latch opens at the beginning of cycle 1 and allows the value of the output of L2 to be available at the input of L3. The dashed box 4205 identifies R2 as acting as a latch between configuration cycles 0 and 1.

FIG. 43 illustrates the connections (i.e., placement and routing decisions) used for implementing a part of path 4000 during configuration cycle 1 of some embodiments. As shown the output of latch 4205 is connected to the input of L3 during this configuration cycle. Also, the output of L3 (which is generated in configuration cycle 1) has to be available at the input of L4 in configuration cycle 2. As shown, the output of L3 is connected to RMUX 1. Since RMUX 1 has to hold the value of the output of L3 until the beginning of configuration cycle 2, RMUX 1 operates as a latch. The latch 4305 opens at the beginning of cycle 2 and allows the value of the output of L3 to be available at the input of L4.

FIG. 44 illustrates the connections (i.e., placement and routing decisions) used for implementing a part of path 4000 during configuration cycles 2 and 3 of some embodiments. As shown, in cycle 2, L4 receives the output of latch 4305. The output of L4 is connected to RMUX R2 which acts as a latch 4405 between cycles 2 and 3. The output of the latch 4405 is available to connect to the input of L5. However, if the beginning of cycle 3 is at time t, the input of L5 is available at time t+d where d is the delay for the signal to propagate from the output of latch 4405 to the input of L5. In some embodiments, the overall timing for this reconfiguration chain fails to meet timing constraints where the timing constraint may include a critical path.

Some embodiments extend the operation of RMUX R2 from cycle 2 into cycle 3 in order to make the input of L5 available at an earlier time and thus allow the reconfiguration chain to meet timing constraints. FIG. 45 illustrates one example of extending an operation of configurable logic circuits in some embodiments. As shown, the output of L4 is connected to RMUX R2 during cycle 2. This signal is allowed to pass through R2 to L5 during cycle 2. R2 continues to hold the value of L4 output through cycle 3. In other words, the operation of latch 4505 is extended from cycle 2 to the next cycle in order to make the input of L5 available at an earlier time. The tradeoff for this gain in execution speed is unavailability of R2 during cycle 3 for being reconfigured to perform other operations.

A. Timing Engine that Considers Reconfiguration Cycles

The operations of a timing module of some embodiments is described by using the exemplary path 4000 that was described above. A timing engine has to estimate the delays associated with the logic circuits (such as LUTs) and interconnect circuits (such as RMUXs). FIG. 46 illustrates a LUT in some embodiments. A LUT can be used as a building block to implement other logic circuits in the IC design. The 3-input LUT 4605 has three inputs 4610-4620 (labeled as inputs a, b, and c). Depending on the inputs 4610-4620, the output 4625 provides the values of the function implemented by the LUT. Some embodiments use one or more multiplexers to implement a LUT.

FIG. 47 conceptually illustrates a multiplexer 4705 that implements the function of LUT 4605. The multiplexer receives a set of configuration data 4730 at its input lines 4735 and receives the LUT's inputs at its control lines 4710-4720. In an IC that is not reconfigurable, the arrival time of the signal at the output of the LUT is the maximum arrival time of the multiplexer 4705 control lines 4710-4720 (which receives the LUT's inputs) plus the delay caused by the LUT. The configuration data is always the same constant and does not affect timing calculation. The configuration data of a LUT is determined by the placer during the IC design.

Similarly, multiplexers can be used to implement RMUXs or IMUXs. However, the inputs of a multiplexer that implements an RMUX (or IMUX) receives the inputs of the RMUX (or IMUX) and control lines of the multiplexer receives the controls of the RMUX (or IMUX). The arrival time of a signal at the output of an RMUX (or an IMUX) is the maximum arrival time of the multiplexer inputs (which receive the RMUX or IMUX inputs) plus the delay caused by the RMUX (or IMUX). The configuration data received at the control lines of the multiplexer is always the same constant and does not affect timing calculation. The configuration data of an RMUX (or an IMUX) is determined by the router during the IC design.

FIG. 48 conceptually illustrates a LUT implemented by a multiplexer 4805 in a reconfigurable IC design in some embodiments. Although only one multiplexer is shown in FIG. 48, some embodiments use a set of multiplexers to implement a LUT. In a reconfigurable design, the configuration data received at the inputs 4835 of the multiplexer can change in different reconfiguration cycles. Therefore, configuration data is provided to the inputs 4835 of the multiplexer from a configuration data storage 4830. A similar design can be used to implement an RMUX or IMUX, except that the configuration data is provided to the control lines of the multiplexer.

FIG. 49 conceptually illustrates a process 4900 that performs timing analysis for a reconfigurable IC design. As shown, the process receives (at 4905) a reconfigurable logic design. The process identifies (at 4910) the IC design components in space fabric. The process then unfolds (at 4915) the logic design into a space-time design to extract space-time information. The process then utilizes the extracted information to perform (at 4920) timing analysis.

FIG. 50 illustrates delay calculation for path 4000 by the timing module of some embodiments. In this figure, the netlist is unfolded to show each of the various circuit elements during the various configuration cycles where each subcycle is required to complete in 1 ns. Delay calculation is performed by computing the wire delays between the circuit elements and the time needed to perform the operation at the various circuit elements.

Beginning at the transition between configuration cycle 0 and 1 (i.e., at 1 ns), the time via 5010 will make a signal available to LUT 5020. In some embodiments, before configuration cycle 1 begins, LUT 5020 will have received configuration data to specify the operation the LUT 5020 is to perform. The delay associated with processing the signal once the LUT 5020 is configured is assumed to be 0.1 ns and the delay for the processed signal to propagate to time via 5030 is assumed to be 0.4 ns. Accordingly, the total delay before the processed arrives at time via 5030 is 1.5 ns and the total time before the signal is made available at the output of the time via 5030 is 1.7 ns based on a 0.2 ns delay associated with the time via 5030. At this point, the time via 5030 must store the signal and make it available at the beginning of configuration cycle 2 as there is inadequate time for the signal to propagate through LUT 5040, RMUX 5060, and LUT 5060 before the output of the netlist is complete.

Accordingly, the time via makes the signal available for LUT 5040 at the beginning of configuration cycle 2. The delays associated with passing the signal from the LUT 5040 to the RMUX 5060 include the processing delay of 0.1 ns of the LUT 5040 and the wiring delay of 0.4 ns. Therefore, the signal is available at the RMUX 5060 at 2.5 ns. Here again, the signal cannot completely propagate to the output of the netlist during configuration cycle 2, because the additional delays of 0.1 ns for routing by the RMUX 5060, 0.4 ns wiring path delay between RMUX 5060 and LUT 5060, and 0.1 for processing by the LUT 5060 causes the signal to be output at 3.1 ns. Therefore, the signal must be stored at the RMUX 5060. Then at the beginning of configuration cycle 3, the signal is routed through the RMUX 5060 with 0.1 ns delay and passes over the wire with 0.4 delay before arriving at the LUT 5060 where processing consumes an additional 0.1 ns of delay. Once complete, the netlist will have finished its operations in a total of 3.6 ns using four sub-cycles.

However, timing of the netlist can be optimized by extending the operation of the RMUX 5060 in accordance with some embodiments of the invention. FIG. 51 illustrates extending the operation of a circuit module in the unfolded netlist of FIG. 50 in order to achieve more optimal timing. FIG. 51 illustrates that by extending the operation of the RMUX 5110 during configuration cycle 2, the signal can be made available to LUT 5120 at the beginning of configuration cycle 3 (i.e., 3.0 ns). Once configuration cycle 3 begins, only 0.1 ns is needed for the signal to pass through the LUIT 5120 in order to complete the logic operation of the netlist. In this manner, extending the operation of the RMUX 5110 allows the netlist to complete its logic operation sooner, improving timing of the netlist, timing of the overall circuit, and thus permitting more operations to be performed in the same amount of time.

B. Advantages of Extending the Operation of Configurable Circuits

A critical path in an IC design is a path whose implementation in the IC chip has to be optimal for any number of reasons. For example, a critical path could be an important path for which the signal has to traverse as fast as possible. A critical path can also be a path that, for example, barely meets its timing requirements. A critical path may also be a path with one of the longest delays in the IC design. In order to speed up the execution of the design, critical paths have to be performed as fast as possible. FIG. 53 illustrates a critical path of some embodiments. The IC in this example is designed to operate in six reconfigurable cycles. In FIG. 53 configurable logic circuits (e.g., LUTs) are shown by circles. One way to speed up the critical path is not to reconfigure any of the LUTs that are used in the critical path. In other words, none of the LUTs used in the critical path are available to perform any other operations during any reconfiguration cycles.

FIG. 54 illustrates the critical path of FIG. 53 through the six reconfiguration cycles. As shown, none of the LUTs in the critical path are reconfigured to perform any other operations. As a result the critical path is performed with minimum possible delays. The tradeoff, however, is to use six times more logic circuits as when the LUTs were allowed to be reconfigured to do other operations.

FIG. 55 illustrates the same critical path, except as it is shown the signal in the first reconfiguration cycle (cycle 0) can only travel through the first three LUTs (as identified by the ellipse around them). The operation of the third LUT is, therefore, extended into reconfiguration cycle 1 to speed up the execution of the critical path. The other LUTs are, however, available to be reconfigured to perform other operations during reconfiguration cycle 0.

FIG. 56 illustrates the same critical path during reconfiguration cycle 1. Again, it is shown that the signal can only travel through the fifth LUT. The operation of the fifth LUT is, therefore, extended into the next reconfiguration cycle. All other LUTs are available to be reconfigured to perform other operations during reconfiguration cycle 1. Also, in order to extend the operation of the third LUT from cycle 0 to cycle 1, a latch (shown as a small square) is placed between the second and third LUTs during cycle 1.

Similarly, FIG. 57 illustrates other LUTs whose operations are extended into other configuration cycles. Also, as shown, other latches placed to prevent the output of other latches to reach the input of the latches that are performing the critical path in each reconfiguration cycle. Specifically, a latch is placed between the fourth and fifth LUTs in cycle 2, a latch is placed between the sixth and seventh LUTs in cycle 3, a latch is placed between the eighth and ninth LUTs in cycle 4, and a latch is placed between the tenth and eleventh LUTs in cycle 5.

Therefore, assuming that the signal in this particular example can go through three LUTs in each configuration cycle, only three LUT in cycles 0-4 and two LUTs in cycle 5 cannot be reconfigured. These LUTs are identified by the conceptual arrow in FIG. 58. All other LUTs are available for being reconfigured to do other operations.

FIG. 59 shows a worst case scenario that every reconfiguration cycle has one LUT whose operation is extended. As a result, a 50% area penalty is paid for the use of the extra LUTs. In practice, however, not every reconfiguration cycle requires the operation of a configurable circuit to be extended. FIG. 60 illustrates a more likely scenario that extended paths incur an extra 25% number of reconfigurable circuits. Also, when a path requires only one extension, the path incurs only an 8% area overhead.

Also, in a typical case, not every reconfigurable cycle starts with a LUT. Some reconfigurable cycles start with an RMUX. FIG. 61 illustrates a path in which cycle 1, 3, and 5 start with an RMUX instead of a LUT. When the path requires extension of the operation of an RMUX instead of a LUT, the extension has less impact on the overall available area since there are more RMUXs than LUTs available in the IC fabric. FIG. 62 illustrates a case that the operation of the first RMUX has to be extended into cycle 1. As shown, the first two LUT and the first RMUX are needed during cycle 0 for performing this path. All other LUTs and RMUX are available to be reconfigured for other operations.

FIG. 63 shows that the fifth LUT is determined to be extended from cycle 1 into cycle 2. The first RMUX (which was extended from previous cycle) and the third to fifth LUTs are needed to perform cycle 1. Finally, FIG. 64 illustrates a scenario in which 3 RMUXs and only two LUTs are extended into next configuration cycles. The overhead for the extra LUTs is, therefore, only 16.6%. This improvement in the use of LUTs results at the same time as no delays have been caused on the critical path.

VIII. Computer System

FIG. 65 presents a computer system with which one embodiment of the invention is implemented. Computer system 6500 includes a bus 6505, a processor 6510, a system memory 6515, a read-only memory 6520, a permanent storage device 6525, input devices 6530, and output devices 6535. The bus 6505 collectively represents all system, peripheral, and chipset buses that communicatively connect the numerous internal devices of the computer system 6500. For instance, the bus 6505 communicatively connects the processor 6510 with the read-only memory 6520, the system memory 6515, and the permanent storage device 6525.

From these various memory units, the processor 6510 retrieves instructions to execute and data to process in order to execute the processes of the invention. The read-only-memory (ROM) 6520 stores static data and instructions that are needed by the processor 6510 and other modules of the computer system.

The permanent storage device 6525, on the other hand, is a read-and-write memory device. This device is a non-volatile memory unit that stores instructions and data even when the computer system 6500 is off. Some embodiments of the invention use a mass-storage device (such as a magnetic or optical disk and its corresponding disk drive) as the permanent storage device 6525.

Other embodiments use a removable storage device (such as a floppy disk or zip® disk, and its corresponding disk drive) as the permanent storage device. Like the permanent storage device 6525, the system memory 6515 is a read-and-write memory device. However, unlike storage device 6525, the system memory is a volatile read-and-write memory, such as a random access memory. The system memory stores some of the instructions and data that the processor needs at runtime. In some embodiments, the invention's processes are stored in the system memory 6515, the permanent storage device 6525, and/or the read-only memory 6520.

The bus 6505 also connects to the input and output devices 6530 and 6535. The input devices enable the user to communicate information and select commands to the computer system. The input devices 6530 include alphanumeric keyboards and cursor-controllers. The output devices 6535 display images generated by the computer system. The output devices include printers and display devices, such as cathode ray tubes (CRT) or liquid crystal displays (LCD).

Finally, as shown in FIG. 65, bus 6505 also couples computer 6500 to a network 6545 through a network adapter (not shown). In this manner, the computer can be a part of a network of computers (such as a local area network (“LAN”), a wide area network (“WAN”), or an Intranet) or a network of networks (such as the Internet). Any or all of the components of computer system 6500 may be used in conjunction with the invention. However, one of ordinary skill in the art would appreciate that any other system configuration may also be used in conjunction with the present invention.

Some embodiments include electronic components, such as microprocessors, storage and memory that store computer program instructions in a machine-readable or computer-readable medium. Examples of machine-readable media or computer-readable media include, but are not limited to magnetic media such as hard disks, memory modules, magnetic tapes, optical media such as CD-ROMs and holographic devices, magneto-optical media such as optical disks, and hardware devices that are specifically configured to store and execute program code. Examples of these hardware devices include, but are not limited to application specific integrated circuits (ASICs), field programmable gate arrays (FPGA), programmable logic devices (PLDs), ROM, and RAM devices. Examples of computer programs or computer code include machine code, such as produced by a compiler, and files including higher-level code that are executed by a computer, an electronic component, or a microprocessor using an interpreter.

While the invention has been described with reference to numerous specific details, one of ordinary skill in the art will recognize that the invention can be embodied in other specific forms without departing from the spirit of the invention. For instance, several embodiments were described above that simultaneously optimize the physical design and sub-cycle assignment of a sub-cycle reconfigurable IC. One of ordinary skill will realize that other embodiments are not to be used for optimizing sub-cycle reconfigurable IC's. For instance, some embodiments are used to optimize simultaneously the physical design and reconfiguration cycle of a reconfigurable IC that does not reconfigure at a sub-cycle basis (i.e., reconfigures at a rate slower than a sub-cycle rate). Thus, one of ordinary skill in the art would understand that the invention is not to be limited by the foregoing illustrative details, but rather is to be defined by the appended claims. 

1. A method comprising: identifying a first physical design solution for positioning a plurality of configurable operations on a plurality of reconfigurable circuits of an integrated circuit (IC); identifying a second physical design solution for positioning the configurable operations on the configurable circuits, wherein one of the identified physical design solutions has one reconfigurable circuit perform a particular configurable operation in at least two reconfiguration cycles while the other identified solution does not have one reconfigurable circuit perform the particular configurable operation in two reconfiguration cycles. costing the first and second physical design solutions; and selecting one of the two physical design solutions based on the costs.
 2. The method of claim 1, wherein the second physical design solution uses a storage element to facilitate having one reconfigurable circuit perform the particular configurable operation in at least two reconfiguration cycles.
 3. The method of claim 2, wherein the storage element is a latch.
 4. The method of claim 1, wherein costing the second physical design solution penalizes the second physical design solution for having one reconfigurable circuit perform the particular configurable operation in at least two reconfiguration cycles.
 5. The method of claim 4, wherein the first and second physical design solutions each have an associated timing cost, wherein having one reconfigurable circuit perform the particular configurable operation in at least two reconfiguration cycles improves the associated timing cost of the second physical design solution.
 6. The method of claim 1, wherein the reconfigurable circuits are reconfigurable logic circuits.
 7. The method of claim 6, wherein the physical design solutions are placement solutions.
 8. The method of claim 1, wherein the reconfigurable circuits are reconfigurable interconnect circuits.
 9. The method of claim 8, wherein the physical design solutions are routing solutions.
 10. The method of claim 1, wherein positioning the plurality of configurable operations on the plurality of reconfigurable circuits comprises assigning a first configurable operation to a first reconfigurable circuit in a first reconfiguration cycle.
 11. The method of claim 10, wherein assigning a first configurable operation to a first reconfigurable circuit in a first reconfiguration cycle comprises defining a first configuration data set as the configuration data set for the first reconfigurable circuit in the first reconfiguration cycle.
 12. A method of implementing an integrated circuit (IC) design, the method comprising: identifying a configurable circuit design comprising a plurality of configurable operations assigned to a plurality of configurable circuits for a plurality of reconfiguration cycle; and extending an operation of at least one reconfigurable circuit from a first reconfiguration cycle into a second reconfiguration cycle.
 13. The method of claim 12, wherein the first reconfiguration cycle occurs prior to the second reconfiguration cycle.
 14. The method of claim 12, wherein the second reconfiguration cycle occurs prior to the first reconfiguration cycle.
 15. The method of claim 12, wherein the first and second reconfiguration cycles are not consecutive reconfiguration cycles, wherein extending the operation of the reconfigurable circuit comprises extending the operation of the configurable circuit across multiple reconfiguration cycles.
 16. The method of claim 12, wherein said at least one configurable circuit comprises a configurable logic circuit.
 17. The method of claim 12, wherein said at least one configurable circuit comprises a configurable interconnect circuit. 